CHECK VALVE MODULE
Background of the Invention The invention relates to check valves .
Check valves are designed to control the direction of flow of a liquid or gas through a conduit. A typical check valve permits flow in one direction, but prohibits flow in an opposite direction.
Summary of the Invention
In general, in one aspect, the invention features a check valve module including a body having a first fluid communicating surface and a second fluid communicating surface, and two one-way check valves in the body controlling flow between the first and second surfaces. One of the valves permits flow from the first surface to the second surface, and the other valve permits flow from the second surface to the first surface . Embodiments of this aspect of the invention may include one or more of the following features. The module body has a first end and a second end. The first fluid communicating surface is on the first end, and the second fluid communicating surface is on the second end. The body also has an outer sealing surface between the first and second fluid communicating surfaces. The outer sealing surface is cylindrical, and has a sealing member, such as an O-ring. The first and second surfaces are circular. The module includes an inlet and an outlet which communicate with the first fluid communicating surface. The inlet can, e.g., be larger than the outlet. The module also has a registration structure for aligning the inlet with an input flow assembly, and the outlet with an
output flow assembly. The registration structure is, e.g., a threaded bore offset from the inlet and outlet.
The threaded bore also communicates with the first fluid communicating surface. The first fluid communicating surface is flat, and has a diameter greater than the diameter of the second fluid communicating surface.
Each one-way check valve in the module has a flow through channel which includes an upstream region, a downstream region, and a blocking structure. The blocking structure permits flow from the upstream region to the downstream region, but prohibits flow from the downstream region to the upstream region. The flow channel further includes a sealing structure, e.g., an inner O-ring, which forms a seal with the blocking structure to prohibit flow from the downstream region to the upstream region.
The blocking structure includes, e.g., a ball disposed within the downstream region. The ball has a diameter greater than the diameter of the inner O-ring, but less than the width of the downstream region. The ball forms a seal with the inner O-ring in the event of flow from the downstream region towards the upstream region. The blocking structure further includes a spring. The spring biases the ball towards the upstream region.
In general, in another aspect, the invention features a bi-directional flow-through assembly. The bidirectional flow-through assembly includes a flow-through conduit having an inner wall and a two-way check valve module disposed within the conduit. The two-way check valve includes a body having a first fluid communicating surface, a second fluid communicating surface, and an outer sealing surface for sealing the body to the inner wall of the conduit. In the body, two check valves
control flow between the first and second surfaces. One check valve permits flow from the first surface to the second surface, and the other valve permits flow from the second surface to the first surface. Embodiments of this aspect of the invention can include one or more of the following features. The outer sealing surface of the body includes an O-ring for forming a seal between the outer sealing surface and the inner wall of the conduit. The first fluid communicating surface has a width greater than the width of the conduit, such that the first fluid communicating surface remains outside of the conduit when the module is disposed within the conduit.
The assembly further includes a piston disposed within the conduit for pumping fluid through said module, and a top plate. The top plate has a first fluid communicating end and a second end for mating with the first surface of the check valve body. The first surface of the module has an inlet and an outlet, and the top plate has an inflow channel and an outflow channel for aligning with the inlet and the outlet. The first surface also has a threaded bore, and the top plate has a clearance hole for aligning with the threaded bore.
Embodiments of the invention have the advantage of including two one-way check valves in the same unitary piece, reducing the number of components needed for the flow assembly. The module is easy to replace, and does not require adjustment.
The registration structure for aligning the inlet with an input flow assembly prevents improperly connecting the input flow assembly to the outlet.
The module can be sealingly engaged to the interior of a rigid tubing, e.g., a cylinder of a positive displacement pump.
Brief Description of the Drawings Figs. 1A and IB are perspective views of a check valve module.
Fig. 2 is an sectional view of the check valve module of Fig. 1.
Fig. 3 is a partially schematic sectional view of the check valve module of Fig. 1 attached to a pump. Fig. 4 is a plan view of the pump of Fig. 3.
Description of the Preferred Embodiments Referring to Figs. 1A and IB, a check valve module 10 includes a top end 12, a bottom end 14, and a sealing surface 16 between top end 12 and bottom end 14.
Top end 12 includes a top fluid communicating surface 18. Top surface 18 is generally flat, and has an inlet 20, an outlet 22, and a threaded alignment bore 24. Bottom end 14 includes a lower fluid communicating surface 26, and one-way check valves 28a, 28b. Sealing surface 16 is generally cylindrical in shape, and has an O-ring 30. Top surface 18 has a diameter Dτ of, e.g., about 3/4 inches, and lower surface 26 has a diameter DL of, e.g., about 5/8 inches.
Referring to Fig. 2, check valve 28a includes a channel 32a, an upstream region 34a, a downstream region 36a, and a flow control structure 38a for preventing flow in the direction of arrow B, from downstream region 36a to upstream region 34a.
Flow control structure 38a includes a blocking ball 40a, a spring 42a, and an inner O-ring 44a. Blocking ball 40a has a diameter D1 which is greater than a diameter D2 of inner O-ring 44a, but less than a diameter D3 of downstream region 36a. Ball 40a engages a first end 46a of spring 42a. A second end 48a of spring 42a engages a shelf 50a within channel 32a.
Check valve 28a defines an output flow-through path 0 from an opening 37a (Fig. 1A) in lower surface 26, through upstream region 34a, past flow control structure 38a, through downstream region 36a, through channel 32a, and outlet 22.
In operation, flow control structure 38a prevents flow from downstream region 36a to upstream region 34a in the following manner. If fluid begins to flow in the direction of arrow B, from downstream region 36a towards upstream region 34a, the fluid will push ball 40a in the direction of arrow B. Ball 40a will compress inner O- ring 44a, forming a seal, and blocking further flow in the direction of arrow B.
Check valve 28b has a similar structure and operation. As with check valve 28a, check valve 28b has a channel 32b, an upstream region 34b, a downstream region 36b, and a flow control structure 38b for preventing flow in the direction of arrow A, from downstream region 36b to upstream region 34b. Check valve 28b is disposed within an insert 54 which can be placed within module 10 during assembly of module 10.
Flow control structure 38b includes a blocking ball 40b, a spring 42b, and an inner O-ring 44b. Blocking ball 40b, upstream region 34b, and downstream region 36b have dimensions similar to the dimensions of ball 40a, region 34a, and region 36a, respectively. As in flow control structure 38a, ball 40b engages a first end 46b of spring 42b, and a second end 48b of spring 42b engages a shelf 50b. Flow control structure 38b operates in the same manner as structure 38a, preventing flow in the direction of arrow A, from downstream region 36b to upstream region 34b.
Check valve 28b defines an input flow-through path I in the opposite direction as path 0, from inlet 20, through upstream region 34b, past flow control structure
38b, through downstream region 36b, and out an opening 37b (Fig. 1A) in lower surface 26. Module 10, therefore, is capable of controlling the flow of fluid in two directions simultaneously. Figs. 3 and 4 illustrate a possible use for module 10 within a bi-directional flow-through assembly 70, e.g. a positive displacement pump. Assembly 70 includes a fluid source 72, a fluid destination 74, a piston cylinder 76, and module 10. Fluid destination 74 can be, e.g., a chromatography column, and fluid source 72 can be, e.g., a chromatography mobile phase solvent. Fluid source 72 connects to inlet 20 through an inflow tube 78 and an inflow connector 80, and fluid destination 74 connects to outlet 22 through an outflow tube 82 and an outflow connector 84. Connectors 80, 84 are pressed against top surface 18 around inlet 20 and outlet 22, respectively, by a connecting plate 86. Connecting plate 86 is attached to cylinder 76 by screws 88a, 88b. The structure and operation of connecting plate 86, and the method for connecting tubes 78, 82 to module 10 is described more fully in co-pending U.S. Patent Application 09/260,916, entitled "Fluid Coupling Assembly and Method, " filed the same date as this application, and incorporated herein by reference in its entirety. Cylinder 76 is cylindrical in shape, and has an inner diameter Dv approximately equal to a diameter DM of module 10. Diameters Dv and DM are both, e.g., about 5/8 inches. Since top surface 18 has a diameter Dτ greater than diameter Dv of cylinder 76, top surface 18 rests above cylinder 76, and a lower lip 89 of top end 12 is pressed against an upper end 90 of cylinder 76 by connecting plate 86. O-ring 30 of sealing surface 16 seals module 10 to an inner wall 92 of cylinder 76. A piston 94 is disposed within cylinder 76, below lower surface 26 of module 10.
In operation, moving piston 94 in the direction of arrow B draws fluid from fluid source 72 , through inflow tube 78, connector 80, and flow-through path I of module 10, and into chamber 96 of cylinder 76. Moving piston 94 in the direction of arrow A pushes fluid from chamber 96 through flow-through path O of module 10, and out connector 84 and tube 82, to fluid destination 74. Check valve module 10, therefore, allows fluid flow from source 72 to destination 74, without allowing any back- flow from destination 74 to source 72.
Assembly 10 can be used, e.g., for pumping fluid samples from a sample source to column chromatography cartridges, as described, for example, in U.S. Patent Application 09/260,915, entitled "Pump Drive Decoupler," filed the same date as this application, and U.S. Patent Application 09/264,846, entitled "Cartridge Sealing Apparatus and Method, " also filed the same date as this application, both of which are incorporated herein by reference in their entirety. Module 10 can be easily removed and replaced simply by removing bolts 88a and 88b and removing an orientation screw 98 (Fig. 4) received in threaded alignment bore 24.
Other embodiments are within the scope of the claims. For example, the dimensions of module 10 and cylinder 76 can be varied. Inlet 20 can have a different size or shape than outlet 22, to ensure that a user properly connects the fluid source and fluid destination to the correct openings. In addition, inlet 20 can be large in order to limit any drop in pressure experienced by liquids pulled into cylinder 76, in order to avoid degassing and cavitation.
The two check valves within module 10 can have structures other than flow controls structures 38a, 38b to control the flow of fluid through module 10. For
example, module 10 might include flaps which allow flow only in one direction.
Assembly 70 can have a pumping mechanism other than a piston, e.g., a diaphragm. What is claimed is: